Method for making a non-detachable microcircuit card

ABSTRACT

A method for mounting a microcircuit module in a card body to make the card non-detachable without damage includes fixing the module ( 22 ) in a cavity ( 12 ) of the card body ( 11 ) with a resin after adjusting the adherence of the resin ( 30 ) on the wall of the cavity ( 12 ) so that it is markedly higher than its adherence on the module ( 22 ).

The invention relates to a method for making a microcircuit card comprising a support card and a module carrying the microcircuit, the module being installed in an open cavity in said support card. A more particular object of the invention is to combat a type of fraud consisting of demounting a module of this kind without affecting its functions, in order to transplant it into another support card.

The development of microcircuit cards in all fields is constantly calling into question security criteria. One of these criteria is the fact that any attempt to extract the module from the support card must lead to failure, i.e. to destruction of the microcircuit and/or its connections. The need to make progress in this field is keenly felt, especially since producing microcircuit identity cards has been envisaged.

The module that is installed in the cavity in the support card comprises a support film forming a printed circuit and carrying the microcircuit on one side. In most of the technologies currently used it is possible to demount the module without destroying it. This is because the module is often stuck to a peripheral flat defined between the open side and the bottom of the cavity, the microcircuit, which is often coated, being housed in the cavity itself. It is relative easy to insert a tool between the edge of the cavity and that of the module, to detach the latter. If this is done carefully, separation does not lead to the destruction of the microcircuit and/or its connections. Adding a drop of adhesive to connect the bottom of the cavity to the coating of the microcircuit has been proposed. However, demounting remains possible if a tool can be inserted between the resin of the coating and the adhesive. Another technique, proposed by the applicant, consists in depositing the resin protecting the microcircuit into the cavity itself and coating the microcircuit with this resin before the resin is polymerized. This technique makes the module more difficult to demount but the results are difficult to control since they depend greatly on the adherence of the resin to the walls of the cavity and in particular to its bottom. The invention aims to improve this technique.

The invention relates more particularly to a method of making a microcircuit card comprising a card body and a module comprising a support film forming a printed circuit carrying said microcircuit on one of its faces, wherein said module is fixed into a cavity in said card body by means of a resin at least partly filling said cavity and surrounding said Microcircuit, characterized in that the adherence of the resin to the wall of the cavity is increased so that it is significantly greater than its adherence to the support film of said module.

The adherence of the resin may be modified by appropriate surface treatment of the walls of the cavity and more particularly of its bottom. This surface treatment, which is reflected in an increase in the roughness and/or in a chemical modification of the treated surface, very significantly increases the adherence of the resin to the treated surface and in particular makes it very much stronger than the adherence of the same resin to the support film of the module. This being so, in the event of a fraudulent attempt to demount the module by inserting a tool between the edge of the cavity and that of the module the force applied results at best in unsticking the support film from the resin, the microcircuit and its connecting wires remaining embedded in the resin attached to the cavity. Consequently, the module demounted in this way becomes unusable.

The success of this type of surface treatment depends in particular on controlling the settings of the surface treatment means.

Paradoxically, in the context of developing the invention, it has been possible to show that it is preferable to make the card body from a plastic material having a low surface energy (typically less than 45 mN/m), i.e. one having an intrinsically weak adherence to the resin usually employed for the coating in the bottom of the cavity, and even to the adhesive for fixing the module to the periphery of the cavity. This is because, starting from a material of this kind with an intrinsically low surface energy, a better correlation is obtained between the setting parameters of the surface treatment means and the adherence obtained after surface treatment. Moreover, as explained later, materials known for their low surface energy, and relatively little used until now in the field of microcircuit cards for this reason, also have the best mechanical strength and thermal characteristics, which offers the prospect of a longer service life of the microcircuit card.

By way of nonlimiting example, the card body can be made so that at least the bottom of the cavity consists of polyethylene terephthalate (PET), polycarbonate or polybutylene terephthalate (PBT). It is not necessary for the whole of the card body to be made from a material of this kind. For example, if the card body is made by laminating a plurality of layers of plastic materials, possibly different materials, it will suffice for the layer at the depth of the bottom of the cavity to be of a plastic material with a low surface energy, for example one of the materials mentioned above. In the case of PET, polyethylene terephthalate film (PETF) in particular may be used.

If the card body is made in this way, i.e. by laminating a plurality of films, the cavity can be produced after lamination, by machining into the thickness of said card body, taking care that this operation is effected to the correct depth to expose the low surface energy plastic material, so that the latter forms the bottom of the cavity. Of course, the machining may be carried out on a one-piece card body, i.e. one made from a solid block of low surface energy plastic material. Another possibility is to mold the card body, in which case the cavity may be formed during molding. The plastic material used for the molding process is chosen for its low surface energy and is one of the materials indicated above, for example.

The surface treatment may comprise laser beam treatment generating mechanical and/or chemical modifications of the treated surface. Good results are obtained with a YAG laser beam generator or a CO₂ laser beam generator.

The treatment may consist in chemical modification of the bottom surface by exposure to ultraviolet rays, for example by means of a lamp, possibly associated with laser treatment using an excimer laser beam generator emitting in the ultraviolet band. Excimer lasers, in particular argon-fluorine and xenon-chlorine lasers, may be used for this purpose.

The surface state of the cavity may also be modified by plasma treatment using a specific gas or in the open air (corona treatment). This type of treatment is reflected in chemical modification of the surface.

Laser treatment has the advantage of combining chemical modifications with the creation of microcavities which encourage increased adherence of the resin.

The operating parameters of the treatment means indicated above may be adjusted precisely to control the modification of the surface state of a plastic material and more particularly of a low surface energy plastic material.

After the operation of adjusting the surface state referred to above, the method is completed in a manner that is known in the art by depositing a required quantity of resin onto the bottom of the cavity treated in this way and placing the module in the cavity so that its microcircuit is surrounded by the liquid resin. The resin is then polymerized. Depending on the type of resin used, polymerization may be obtained by heat treatment or by ultraviolet irradiation followed by heat treatment after mounting the module. The adhesive used to fix the module to the peripheral flat of the cavity may be a cold adhesive or a heat-activated adhesive. After polymerization, resin adheres both to the interior surface of the module and to that of the treated cavity. However, the adherence of the resin to the module is much lower than the adherence of the same resin to the bottom of the cavity. This results in destruction of the module in the event of an attempt to extract it.

The invention will be better understood and its other advantages will become more clearly apparent in the light of the following description of one embodiment of the method conforming to the invention, which is given by way of example only and with reference to the appended drawings, in which:

FIG. 1 is a diagram showing the fabrication of the card body and the cavity;

FIG. 1 a shows a variant of the FIG. 1 step;

FIG. 2 shows surface treatment of the bottom of the cavity;

FIG. 3 shows implanting a microcircuit module in the cavity;

FIG. 4 shows the finished card; and

FIG. 5 shows destruction of the module in the event of a fraudulent attempt to extract it.

The method of the invention comprises the successive operations shown in FIGS. 1 to 5. In FIG. 1, a card body 11 is formed from a plastic material having a low surface energy. In this example, the card body is molded and a cavity 12 is formed during the molding operation by the particular shape of one of the components of the mold 14. As shown in FIG. 1 a, 1 f the card body 11 a is cut out from a thin sheet of plastic material, the cavity 12 a may be formed by mechanical machining. As previously indicated, if the card body is made by laminating a plurality of films of different plastic materials, then the film at the maximum machining depth may be of a low surface energy plastic material since this film, constituting the bottom of the cavity, must undergo the treatment envisaged.

FIG. 2 depicts diagrammatically one of these surface treatments, namely exposure of at least the bottom 16 of the cavity 12 to a laser beam 18 produced by a generator 19, for example a YAG generator. In the example shown, the cavity comprises a peripheral flat 20 on which the edge of the module rests. This peripheral flat may be subjected to the same treatment.

FIG. 3 shows a standard module 22 consisting of a support film 23 forming a printed circuit defining metal connecting lands 24, 25. A microcircuit 26 is stuck to the other side of the printed circuit. Its inputs-outputs are connected by wires 28 to the various connecting lands of the printed circuit. A heat-activated adhesive 29 is deposited at the periphery of the face of the support film 23 that carries the microcircuit 26. A predetermined quantity of resin is also deposited in the cavity and the module 22 is positioned in the cavity so that the microcircuit is surrounded by the still liquid resin. The adhesive 29 remains on the peripheral flat 20 of the cavity. When the module has been installed in this way, the still liquid resin fills substantially all of the cavity or at least a major portion thereof. The resin is in particular in contact with the interior face of the support film 23 all around the microcircuit. The resin surrounds the microcircuit. This situation is depicted in FIG. 4. When the resin is polymerized, the module adheres perfectly to the card body 11. In the event of an attempt at fraud, the resin 30 coating the microcircuit 26 and its connection wires 28 remain stuck to the bottom of the cavity, whereas the support film 23 of the module is detached from the resin, leading to separation of the connecting wires 28 and the microcircuit 26, on the one hand, from the electrical connection lands 25, on the other hand. The module therefore becomes unusable and may not be installed in another card body. 

1. Method of making a microcircuit card comprising a card body (11) and a module (22) comprising a support film (23) forming a printed circuit carrying said microcircuit (26) on one of its faces, wherein said module is fixed into a cavity (12) in said card body by means of a resin at least partly filling said cavity and surrounding said microcircuit, characterized in that the adherence of the resin (30) to the wall of the cavity (12) is increased so that it is significantly greater than its adherence to the support film (23) of said module.
 2. Method according to claim 1, characterized in that said card body (11) is made from a low surface energy plastic material and in that the surface state of at least a portion of said cavity (12) is modified to increase the adherence of said resin to the treated surface.
 3. Method according to claim 2, characterized in that said card body (11) is made so that at least the bottom of said cavity (12) consists of polyethylene terephthalate (PET).
 4. Method according to claim 2, characterized in that said card body (11) is made so that at least the bottom of said cavity (12) consists of polycarbonate.
 5. Method according to claim 2, characterized in that said card body (11) is made so that at least the bottom of said cavity (12) consists of polybutylene terephthalate (PBT).
 6. Method according to claim 2, characterized in that said card body (11) is made by laminating a plurality of layers of plastic material and in that the layer that forms the bottom of the cavity consists of a low surface energy plastic material.
 7. Method according to claim 1, characterized in that, in a manner that is known in itself, said cavity (12 a) is formed by machining into the thickness of said card body.
 8. Method according to claim 1, characterized in that said card body (11) is made by molding, said cavity (12) being formed during said molding.
 9. Method according to claim 2, characterized in that the surface state of the cavity is modified by laser treatment (18) generating mechanical and/or chemical modifications of the treated surface.
 10. Method according to claim 9, characterized in that said laser treatment is effected by means of a YAG laser beam generator (19).
 11. Method according to claim 9, characterized in that said laser treatment is effected by means of an excimer laser beam generator.
 12. Method according to claim 2, characterized in that the surface state is modified by means of a gas plasma treatment.
 13. Method according to claim 2, characterized in that the surface state is modified by means of a corona treatment.
 14. Method according to claim 2, characterized in that the surface state is modified by means of an ultraviolet treatment.
 15. Method according to claim 2, characterized in that, after the surface state modification operation, a required quantity of resin (30) is deposited on the bottom of said cavity, said module (22) is positioned in said cavity so that its microcircuit (26) is surrounded by the liquid resin, and said resin is polymerized. 